A winch-winding assembly for use with a flatbed winch, for example. The winch-winding assembly can be used for winding tie-down straps. The winch-winding assembly can include a gear system, a drive shaft connected to the gear system in order to cause rotation of the gear system and an engagement arm being configured to engage with and rotate part of the flatbed winch. A drill-support mechanism can be further provided to guide or support a body of a hand-held drill during engagement and rotation of the drive shaft. The engagement arm can comprise a stem and a finger mounted to the stem and being displaceable between a retracted position disengaging the flatbed winch, and an extended position engaging the flatbed winch, to rotate the winch drum in response to rotation of the stem.
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1. A winch-winding assembly connectable to a flatbed winch for winding tie-down straps, the flatbed winch comprising a winch drum having an open end and a lateral opening, the winch-winding assembly comprising:
a gear system;
a drive shaft connected to the gear system and being rotatable about a longitudinal axis thereof in order to cause rotation of the gear system;
an engagement arm configured to engage with and rotate the winch drum, the engagement arm comprising:
a stem rotatable about a longitudinal axis thereof and comprising:
a proximal portion attached to the gear system to be rotated thereby; and
a distal portion extending away from the gear system; and
a finger mounted to the stem and being pivotable between:
a retracted position where the finger is retracted sufficiently to allow the distal portion to be axially insertable with respect to the open end of the winch drum; and
an extended position where the finger extends through the lateral opening of the winch drum in order to engage and rotate the winch drum in response to rotation of the stem.
20. A winding assembly connectable to a winding device for winding an elongated flexible structure, the winding device comprising a drum having an open end and a lateral opening, the winding assembly comprising:
a gear system;
a drive shaft connected to the gear system and being rotatable about a longitudinal axis thereof in order to cause rotation of the gear system;
the gear system comprising a worm gear set comprising:
a worm integrally connected to the drive shaft; and
a worm wheel;
an engagement arm configured to engage with and rotate the drum, the engagement arm comprising:
a stem rotatable about a longitudinal axis thereof and comprising:
a proximal portion attached to the worm wheel to be rotated thereby; and
a distal portion extending away from the gear system; and
the stem of the engagement arm being configured to be perpendicular with respect to the drive shaft;
a finger mounted to the stem and being displaceable between:
a retracted position where the finger is retracted sufficiently to allow the distal portion to be axially insertable into or over the drum to align with the lateral opening; and
an extended position where the finger extends through the lateral opening of the winch drum in order to engage and rotate the drum in response to rotation of the stem;
wherein the finger is configured to pivot from the retracted position to the extended position in response to rotation of the stem.
15. A winch-winding assembly connectable to a flatbed winch for winding tie-down straps, the flatbed winch comprising a winch drum having an open end and a lateral opening, the winch-winding assembly comprising:
a gear system;
a drive shaft connected to the gear system and being rotatable about a longitudinal axis thereof in order to cause rotation of the gear system;
the gear system comprising a worm gear set comprising:
a worm integrally connected to the drive shaft; and
a worm wheel;
an engagement arm configured to engage with and rotate the winch drum, the engagement arm comprising:
a stem rotatable about a longitudinal axis thereof and comprising:
a proximal portion attached to the worm wheel to be rotated thereby; and
a distal portion extending away from the gear system; and
the stem of the engagement arm being configured to be perpendicular with respect to the drive shaft;
a finger mounted to the stem and being displaceable between:
a retracted position where the finger is retracted sufficiently to allow the distal portion to be axially insertable into or over the winch drum to align with the lateral opening; and
an extended position where the finger extends through the lateral opening of the winch drum in order to engage and rotate the winch drum in response to rotation of the stem;
wherein the finger is configured to pivot from the retracted position to the extended position in response to rotation of the stem.
3. The winch-winding assembly of
a worm integrally connected to the drive shaft; and
a worm wheel connected to the proximal portion of the stem.
4. The winch-winding assembly of
6. The winch-winding assembly of
7. The winch-winding assembly of
8. The winch-winding assembly of
9. The winch-winding assembly of
10. The winch-winding assembly of
11. The winch-winding assembly of
13. The winch-winding assembly of
14. The winch-winding assembly of
16. The winch-winding assembly of
17. The winch-winding assembly of
18. The winch-winding assembly of
19. The winch-winding assembly of
21. The winding assembly of
22. The winding assembly of
23. The winding assembly of
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This patent application claims the benefit of U.S. Patent No. 62/212,678 filed on 1 Sep. 2015 and priority to Canadian Patent Application No. 2930713 filed on 19 May 2016. The entire disclosures of each of the above recited applications are incorporated herein by reference.
The technical field generally relates to winches for flatbeds, and more particularly, relates to a winch-winding assembly for use with a flatbed winch for winding tie-down straps or other winding or rotation applications.
Cargo tie-downs, also called hold downs or lashing straps, are commonly used to secure loads on open top compartments, such as truck trailers. The strap, band or cord is tensioned across the load to secure the load to the vehicle.
Typically, a flatbed winch is used to wind the straps tightly around the load. The use of multiple flatbed winches and straps can be desirable for securing large loads. When using a typical flatbed winch, the winding of the winch becomes increasingly difficult as the straps are being tightened. A rod can often be used to act as a lever that connects to part of the winch such that a user can forcibly push downward on the rod to tighten the straps.
However, using a rod to manually wind the winch has various disadvantages, such as increased risk of injury and inefficiency.
There is a need for a winch-winding assembly that overcomes at least some of the disadvantages of what is known in the art.
In some implementations, there is provided a winch-winding assembly connectable to a flatbed winch for winding tie-down straps, the flatbed winch comprising a winch drum having an open end and a lateral opening, the winch-winding assembly comprising:
In some implementations, the gear system comprises a worm gear set.
In some implementations, the worm gear set comprises a worm integrally connected to the drive shaft; and a worm wheel connected to the proximal portion of the stem.
In some implementations, the drive shaft is configured to be perpendicular with respect to the stem of the engagement arm.
In some implementations, the stem comprises a tubular wall defining a channel and having a lateral aperture, and wherein the finger is mounted within the channel.
In some implementations, the finger is mounted and configured so as to be fully housed within the channel in the retracted position and to partially extend through the lateral aperture in the extended position.
In some implementations, the finger is pivotally mounted within the channel to be pivotable between the retracted position and the extended position.
In some implementations, the engagement arm further comprises an end cap fitted on an extremity of the distal portion, the end cap comprising a hinge extending within the channel and to which the finger is pivotally mounted.
In some implementations, the hinge is offset with respect to the longitudinal axis of the stem.
In some implementations, the finger is mounted to the hinge and configured to pivot to the extended position in response to rotation of the stem in a winch-tightening direction, and to pivot to the retracted position in response to rotation of the stem in a winch-loosening direction.
In some implementations, the drive shaft is configured to be engaged by a hand-held drill to effect the rotation thereof.
In some implementations, the stem is a solid structure.
In some implementations, the proximal portion of the stem is cylindrical and the distal portion of the stem is partial-cylindrical.
In some implementations, the distal portion has a cross-section that is a segment of a circular cross-sectional of the proximal portion.
In some implementations, segment is spaced away from a cross-sectional center of the proximal portion.
In some implementations, the finger comprises a finger opening that is mounted about a fastener that is fixed within the stem.
In some implementations, the fastener extends axially into the stem, and the finger is radially pivotable about the fastener.
In some implementations, the fastener is offset with respect to a cross-sectional center of the proximal portion.
In some implementations, the finger is a single one-piece structure.
In some implementations, the finger has a shape such that an outer edge of the finger generally follows contours of the proximal portion of the stem.
In some implementations, the finger has a generally quarter-stadium cross-sectional shape.
In some implementations, there is provided a winch-winding assembly connectable to a flatbed winch for winding tie-down straps, the winch-winding assembly comprising:
In some implementations, the rotating mechanism comprises a chuck of the hand-held drill.
In some implementations, the rotating mechanism comprises a driver bit of the hand-held drill.
In some implementations, the support arm comprises a plate fixed to and extending from an upper end of the gear box.
In some implementations, the plate is spaced apart from and generally parallel with respect to the drive shaft.
In some implementations, the collar comprises a closed annular member defining a generally circular insertion region.
In some implementations, the collar is made from a rigid material.
In some implementations, the collar comprises an upper member attached to an extremity of the distal section of the support arm; and a lower member attachable to the upper member.
In some implementations, the upper member and the lower member are generally U-shaped.
In some implementations, the drill-support mechanism further comprises at least one fastener for attaching the upper member to the distal section of the support arm.
In some implementations, the distal section of the support arm includes at least one opening for receiving the at least one fastener.
In some implementations, the upper member includes a protrusion extending radially from the upper member and adapted to receive the at least one fastener.
In some implementations, the upper member includes at each end thereof a lug comprising an aperture and the lower member includes at each end thereof a corresponding lug comprising an aperture, the lugs of the upper member abutting with respective lugs of the lower member to align the corresponding apertures and form lug pairs that are connectable together to attach the lower member to the upper member.
In some implementations, the collar further includes a plurality of lug fasteners, each lug fastener being insertable through the apertures of a corresponding lug pair for securing the lug pair together, thereby for attaching the lower member to the upper member.
In some implementations, the assembly includes one of more additional features described herein.
In some implementations, there is provided a winch-winding assembly connectable to a flatbed winch for winding tie-down straps, the flatbed winch comprising a winch drum having an open end and a lateral opening, the winch-winding assembly comprising:
In some implementations, such an assembly further includes additional features regarding the stem and finger as described herein.
In some implementations, the engagement arm is configured for insertion into the winch drum, and the finger extends outwardly through the lateral opening of the winch drum in order to engage and rotate the winch drum in response to rotation of the stem.
In some implementations, there is provided a winch-winding assembly connectable to a flatbed winch for winding tie-down straps, the flatbed winch comprising a winch drum having an open end and a lateral opening, the winch-winding assembly comprising:
In some implementations, there is provided a kit comprising a drill and a winch-winding assembly as defined herein, wherein the drill is mountable to the winch-winding assembly via the drill-support mechanism. In some implementations, the drill comprises a neck having an annular surface having a shape and size generally corresponding to the collar for being secured thereby.
In some implementations, there is provided a winding assembly for winding a drum having an open end, the winding assembly comprising:
In some implementations, the distal portion is configured so that a finger is positioned relative thereto, the finger being pivotable or otherwise displaceable between a retracted position where the finger is retracted sufficiently to allow the distal portion to be axially insertable with respect to the open end of the winch drum; and an extended position where the finger extends through a lateral opening of the drum in order to engage and rotate the drum in response to rotation of the stem.
In some implementations, the distal portion comprises a block for insertion within the open end of the drum. The block can include a solid structure having a square cross-section, particularly when the open end of the drum cavity has a corresponding square cross-section. The block may be configured for cooperation with a rotatable drum used in railway applications. There may be two blocks extending from either side of the gear box.
In some implementations, the winding assembly has one or more additional features as described or illustrated herein. The assemblies described herein can also be used in other winding or rotation applications in various industries.
In some implementations, the engagement arm is removably connectable to the gear system. In other implementations, the engagement arm is permanently fixed to the gear system.
The components, advantages and other features of winch-winding assembly implementations will become more apparent upon reading of the following non-restrictive description of some optional configurations, given for the purpose of exemplification only, with reference to the accompanying drawings.
The present invention generally relates to a winch-winding assembly, which can be connectable to a flatbed winch for winding tie-down straps. Advantageously, the winch-winding assembly has a rotatable element that can be coupled to part of the flatbed winch without structurally modifying the flatbed winch. In some implementations, the winch-winding assembly includes an engagement arm that is configured to facilitate coupling to the winch and/or includes a drill-support mechanism configured to facilitate guiding or supporting a drill or a hand-held drill used to drive the winch-winding assembly.
The term “hand-held drill” can include any portable powered device adaptable for causing a rotation of the winch-winding assembly.
Referring to
With reference to
In the illustrated embodiment of
The worm gear set 22 can be configured to produce a velocity ratio, defined as the input rotational velocity of the hand-held drill 36 over the output rotational velocity, between 1 and 50, between 2 and 30, or between 5 and 20 for example. Preferably the velocity ratio is 10.
Referring to
In the illustrated embodiment shown in
In operation, the hand-held drill 36 can be activated to rotate a drill chuck 34 thereof and consequently rotate the drive shaft 28.
In some embodiments, the winch-winding assembly 10 also includes an engagement arm 32 configured to engage with and rotate the winch drum 14. The engagement arm 32 can be a cylindrical elongated structure capable of transmitting a rotational movement between two rotary parts.
With reference to
In addition, the stem 38 includes a proximal portion 40 attached to the gear system 20 to be rotated thereby, and a distal portion 42 extending away from the gear system 20. For example, the worm wheel 26 can be connected to the proximal portion 40 of the stem 38. The connection can be achieved using a fastener, press-fitting the stem 38 into an opening in the worm wheel 26 or any other suitable means.
The drive shaft 28 can be configured to be perpendicular with respect to the stem 38 of the engagement arm 32. This configuration may be more efficient when using a worm gear set 22 since the axis of rotation of the worm 24 is generally perpendicular to the axis of rotation of the worm wheel 26.
Referring to
In a preferred embodiment, the finger 48 can be mounted and configured so as to be fully housed within the channel 50 in the retracted position 52 and to partially extend through the lateral aperture 46 in the extended position 54. The partial extension of the finger 48 is preferably sufficient to securely engage the winch drum 14 through the lateral opening 18 and to prevent unintentional disengagement with the winch drum 14.
In the illustrated embodiment shown in
In one embodiment, as shown in
Referring back to
The hinge 58 can be any device connecting the finger 48 to the engagement arm 32 in order to pivot the finger 48 between the retracted position 52 and the extended position 54. In a preferred embodiment, the hinge 58 is offset with respect to the longitudinal axis of the stem 38. The offset distance can be provided depending on the length and configuration of the finger 48.
In operation, the finger 48 is mounted to the hinge 58 and configured to pivot to the extended position 54 in response to rotation of the stem 38 in a winch-tightening direction, and to pivot to the retracted position 52 in response to rotation of the stem 38 in a winch-loosening direction.
In accordance with another optional aspect, the winch-winding assembly is configured for supporting a hand-held drill.
Referring to
Referring to
In the illustrated embodiment, the support arm 126 has a proximal section 130 connected to the gear box 120 and a distal section 132 extending away from the gear box 120. The support arm 126 can be any rigid structure connecting the gear box 120 with the collar 128 and may be composed of one or multiple elements. The support arm 126 may also comprise a telescoping structure 160 for adjusting the distance of the collar 128 with respect to the gear box 120 and drive shaft 28. In the illustrated embodiment of
In the illustrated embodiment, the collar 128 is connected to the distal section 132 of the support arm 126 and defines an insertion region 134 in which the hand-held drill 36 is guidable so as to engage the drive shaft 28. The collar 128 is spaced away from the drive shaft 28 and can be configured such that the collar 128 abuts on and supports a body of the hand-held drill 36 during engagement and rotation of the drive shaft 28. The term “collar” refers to a component or device comprising parts for at least partially confining, encircling or defining an opening for part of the body of the hand-held drill 36. In the illustrated embodiment of
In the illustrated embodiment of
Referring to
With reference to
The collar 128 can further include a plurality of lug fasteners 158, each lug fastener 158 being insertable through the apertures 150, 154 of a corresponding lug pair 156 for securing the lug pair 156 together, thereby attaching the lower member 140 to the upper member 138.
In operation, the hand-held drill 36 is inserted into the insertion region 134 of the collar 128 and guided so as to engage the drive shaft 28. The hand-held drill 36 can then be activated in order to cause rotation of the gear system 20 and consequently rotation of the engagement arm 32 for winding the flatbed winch 12. Advantageously, in some embodiment the drill-support mechanism 124 is configured to substantially reduce and/or limit transmissible torque, produced during the winding process, on a handle of the hand-held drill 36 by confining and securing the hand-held drill 36 in place.
In some implementations, the gear system is configured so that, when used with a drill and high resistance to rotation is encountered, the drill will shut down or stutter before the gears are damaged.
Referring now to
Referring to
In some implementations, the proximal portion 40 of the stem 38 can be cylindrical. The distal portion 42 can be generally half-cylindrical or partial-cylindrical, as illustrated in
Referring to
Referring still to
It is noted that certain components can be sized to provide an amount of play therebetween. For example, the fastener that pivotally retains the finger can be slightly smaller than the hole in the finger through which is passes, providing an amount of play. In addition, the finger can be sized and configured so that there is an amount of play in between its rear end and the inner surface of the distal portion to facilitate pivoting from closed to open positions, as illustrated in
Turning now to
Referring to
Referring to
Referring now to
Referring now to
It is also noted that embodiments of the winch-winding assembly described and illustrated herein can also be used with or adapted for winding applications other than winding tie-down straps using a flatbed winch. In some scenarios, the winch-winding assembly can be used for winding a winch or other type of rolling device for winding an elongated flexible structure, such as a tube, a hose, a cord, an electrical wire or line, an extension cord, a strap or other type of flat flexible elongated element, and the like. In some scenarios, the winding assembly 10 is used for elongate flexible elements that still have some rigidity, such as cold or ice-coated straps, in order to reform the elongate elements around the winding drum. In other implementations, the assembly 10 can be used with a drill or another type of drive device for engaging with and rotating various different rotatable shafts in different applications. In some scenarios, embodiments of the winding assembly can be used in conjunction with a manual crank or another manual drive device rather than a drill or motorized drive device. The drill-support mechanism could be adapted to support and/or guide other types of motorized or manual drive devices.
Referring to
The winding assembly 10 can be manufactured and sold alone for a pre-determined purpose, such as flatbed tie-down straps, or a variety of end uses. In some scenarios, the winding assembly 10 can be provided as part of a pre-assembled drill-and-assembly unit (as illustrated in
In some implementations, the winding assembly 10 can include two engagement arms 32 extending from opposed sides (e.g., of the gear box) to enable cooperation with a winch device or the like from either direction. This can be useful particularly for scenarios where drums of different types, constructions or accessibilities are to be rotated. In addition, the engagement arm can be configured to be removably connectable to the gear box such that a single arm component can be used on either side of the gear box.
In some implementations, referring to
In some implementations, the winding assembly 10 having a block engagement arm can be used for train or railway applications where rotatable drums/shafts having square-shaped cavities are used. The block can be inserted within the square cavity of the shaft, and then rotated in order to exert rotational force on the shaft to enable rotation. Square cavity shafts used in the railway industry can be accessible from only one direction, and thus the winding assembly 10 can have two blocks extending from either side of the gear box in order to facilitate insertion and rotation from either side.
In some implementations, the engagement arm can be removably connectable to the gear system via a connection mechanism, which may include a quick-clip mechanism, lip-and-groove, nodule-and-groove, magnetic, and/or other types of connections. It should be noted that engagement arms of different types, sizes and/or configurations can be provided for different applications. For example, a set of engagement arms can be provided and can be removably connectable to the gear system. At least one of the engagement arms can be a stem-and-finger type as described as illustrated herein. In some scenarios, engagement arms can be provided to be removably connectable to both sides of the gear system; for instance, one engagement arm can be configured to be connectable to a first side of the gear system and another engagement arm can be configured to be connectable to a second side of the gear system, with the two engagement arms being configured to have the appropriate orientation for engaging and rotating a winch drum or other type of rotatable element from the respective sides. The set of engagement arms can includes arm adapters designed for specific applications, such flatbed winch drum winding, rotation of drum or other rotatable elements used in railway applications, and other rotation applications, particularly applications that require a 90 degree angle between the drill drive direction and the rotation axis. The connection mechanism for mounting the arms to the gear system can include a connector portion protruding out from the gear system and having a structure enabling the arms to fit over or within the connector portion to become rotationally fixed relative to the connector portion. Thus, when the connector portion is rotated by the gear system, the arm can be rotated accordingly. In some scenarios, the connector portion can be similar or identical to the block as illustrated herein, and the arms can include a proximal portion that connects relative to the block.
In some scenarios, the winding assembly 10 may be used with a Makita™ drill, preferably used in screw-mode at a level of 7 or 8. The collar can be configured to attach to the neck of the drill where a drill-grip could be connected.
In the above description, the same numerical references refer to similar elements. Furthermore, for the sake of simplicity and clarity, namely so as to not unduly burden the figures with several reference numbers, not all figures contain references to all the components and features, and references to some components and features may be found in only one figure, and components and features of the present invention illustrated in other figures can be easily inferred therefrom. The embodiments, geometrical configurations, materials mentioned and/or dimensions shown in the figures are optional, and are given for exemplification purposes only.
Furthermore, although the present invention may be used with various objects, such as flatbed winches, for example, it is understood that it may be used with other winding objects. For this reason, expressions such as “flatbed winch”, “winch”, etc. as used herein should not be taken as to limit the scope of the present invention to these devices, on which a rope or strap is to be wound, in particular. These expressions encompass all other kinds of materials, objects and/or purposes with which the present invention could be used and may be useful, as can be easily understood.
Girard, Vincent, Taillon, Michel, Fortin, Jacques, Bujold, Hermel, Thériault, Pierre
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